Hooke's Law

Page 1

Figure 1

When we apply a force to a spring, it stretches or compresses. The spring’s extension or compression is proportional to the applied force: đ??š = đ?‘˜đ?‘Ľ

(1)

Where: F = The applied force x = The spring’s extension k = The spring constant This law is known as Hooke’s Law. It enables us to use the extension or compression of the spring to measure force.


In this experiment we will use the Force sensor and the Distance sensor to calibrate a spring for use as a dynamometer (force meter).

einstein™Tablet+ with MiLAB or Android/iOS Tablet with MiLAB and einstein™LabMate Force sensor Distance sensor Distance adaptor Spring (~15 N/m) Slotted mass set Slotted mass hanger Stand and supporting rod (2) Clamp with hook to hang the spring

1.

Launch MiLAB (

2.

Connect the Distance sensor with the Distance adaptor to one of the ports on the einstein™Tablet+ or einstein™LabMate. Connect the Force sensor to one of the ports on the einstein™Tablet+ or einstein™LabMate. Assemble the equipment as shown in Figure 1. a. Make sure there are no physical obstacles between the hanging mass and the Distance sensor. b. Use a mass of 100 g. c. The distance between the mass and sensor should be about 70 cm. Make sure that the Distance sensor and the Force sensor are the only sensors selected.

3. 4.

5.

).

Program the sensors to log data according to the following setup: Distance Sensor

Distance (m)

Force Sensor

Force, Pull - positive ( 10 N) (N)

Set As Zero

ON

Rate:

10 samples/ sec

Duration:

2 Min

1.

Make sure that the hanging mass is at rest.

2.

Tap Run (

3.

Wait 20 seconds and then add a weight of 50 g to the hanging mass so that the total mass is now 150 g. Bring the mass to rest.

) on the upper toolbar to begin recording data.


4. 5.

Wait another 20 seconds then add again a mass of 50 g and bring the mass to rest. Repeat step 4 and increase the hanging mass by amounts of 50 g until you reach 500 g.

6.

Tap Stop (

7.

Save your data by tapping Save (

8.

Use two cursors to determine the spring’s extension for each hanging mass. Record these values in the data table.

Hanging Mass (g.)

). ) on the upper toolbar.

Applied Force (N)

Extension (m)

100 150 200 250 300 350 400

For more information on working with graphs see: Working with Graphs in MiLAB. 1. 2.

What was the force applied to the spring when the hanging mass was 100 g? Use data from the Force sensor to fill in the Applied Force column in the data table, recording force in units of Newtons. 3. Use data from the Distance sensor to fill in the Extension column in the data table, recording extension in units of meters. 4. Plot a graph of the applied force versus the spring’s extension. 5. Fit a straight line to your data points that passes through the origin. 6. What are the units of the slope? Use the graph to calculate the spring constant, k.


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